Valve Actuation Control for Flush Urinal and Toilet Apparatus

ABSTRACT

An actuation control for a flush system includes a cartridge valve being actuated between an opened position and a closed position to compete a flushing cycle. The cartridge valve includes a cartridge housing having a valve inlet for communicating with a water source and the valve outlet for guiding water to flow to the flush system, and a control disc unit which is supported in the cartridge housing at the valve inlet thereof and is orientated perpendicular to a water-in direction of the water for biasing against water pressure from said water source. At the closed position, the valve inlet is closed by the control disc unit for blocking the water to pass through the valve inlet. At the opened position, the valve inlet is opened up for allowing the water passing to the valve outlet so as to complete the flushing cycle of the flush system.

NOTICE OF COPYRIGHT

A portion of the disclosure of this patent document contains materialwhich is subject to copyright protection. The copyright owner has noobjection to any reproduction by anyone of the patent disclosure, as itappears in the United States Patent and Trademark Office patent files orrecords, but otherwise reserves all copyright rights whatsoever.

BACKGROUND OF THE PRESENT INVENTION Field of Invention

The present invention relates to a flush apparatus, and moreparticularly to a valve actuation control for the flush urinal andtoilet apparatus, which comprises a cartridge valve to be selectivelyactuated between an opened position and a closed position for completinga flushing cycle of the flush apparatus without any requirement of watercavity or diaphragm.

Description of Related Arts

Manual operated toilet room flush valves for use on urinals and waterclosets in public restrooms are well known. A conventional manualoperated flush actuation apparatus comprises a valve body defining awater cavity and having a water inlet, a water outlet, a diaphragmhaving a water channel communicating between the water inlet and thewater outlet, a relief valve disposed at the diaphragm for blocking thewater flowing from the water inlet to the water outlet through the waterchannel, and a flush lever arranged to move the relief valve at aposition that the water is allowed to flow to the water outlet forcompleting the flushing operation of the flush apparatus. Accordingly,the diaphragm is supported within the water cavity that water ispre-filled in the water cavity to generate a predetermined waterpressure at the diaphragm. Once the relief valve is moved, the diaphragmis popped to release the water pressure within the water cavity torelease the water from the water inlet to the water outlet. Once thediaphragm is returned back to its original position, the water cavity issealed to re-fill the water therein to re-gain the water pressure. Inother words, the water pressure is needed for pushing the diaphragm toseal the water outlet, such that the diaphragm bears the water pressureall the time.

For hygiene purposes, an automatic operated toilet room flush valve isdeveloped. For example, a solenoid operated automatic flush valve, whichis battery-operated, utilizes a latching solenoid to limit power drainon the battery. Accordingly, when the infrared sensor detects thepresence of a user of a urinal or toilet, the flush valve isautomatically driven to open to complete the flushing operation.However, the flush valves have several common drawbacks.

The flush valve must be big enough to provide the water cavity. It isworth mentioning that the diaphragm and the relief valve are disposed inthe water cavity. Therefore, the water cavity should be big enough toallow the movements of the diaphragm and the relief valve. In addition,a predetermined volume of the water must be filled in the water cavityto create the water pressure therewithin. Furthermore, the water must bere-filled in the water cavity after every flushing completion.

The flush valve must be incorporated with the diaphragm to retain thewater pressure within the water cavity. It is worth mentioning that thediaphragm is made of elastic material such that the diaphragm can bepopped to release the water pressure within the water cavity. However,the diaphragm will gradually lose its elasticity and will gradually wearout after the period of usage time and the diaphragm is easily broken ordamaged due to the popping movement of the diaphragm. It is recommendedthat the diaphragm should be replaced every year to keep the flush valvein good working condition. In other words, the service lifespan of thediaphragm is shorter than that of the flush valve, such that thediaphragm must be replaced frequently comparing with other components ofthe flush valve.

Alternatively, a pistol can be a replacement of the diaphragm to controlthe flush valve between the opened position and the closed position. Inparticular, the pistol is moved along the water inflow direction, suchthat when the pistol is moved against the water inflow direction, theflush valve is moved at the closed position and when the pistol is movedat the water inflow direction, the flush valve is moved at the openedposition. In other words, the flush valve must be operated to provide astrong actuating force that is strong enough to move the pistol againstthe water inflow direction. Accordingly, the conventional flush valve,including the diaphragm or pistol type, bears the water pressure between20 and 150 psi all the time. In addition, the conventional flush valveis operated to push the diaphragm or the pistol against the water inflowdirection from the water source.

The presence of the user sensed by the infrared sensor will cause thesolenoid to move the diaphragm to a valve open position. It is knownthat the solenoid is made of a number of circular wire loops to generatea magnetic force when an electric current is passed through the wireloops. The solenoid may come in contact with water such that thesolenoid may accumulate rusting particles from the water, which mayremain on the solenoid. It is one of the common problems to cause afailure of operation of the flush valve. In other words, theconventional manual operated flush valve is more reliable than thesolenoid operated automatic flush valve. Thus, the maintenance cost ofthe solenoid operated automatic flush valve is higher than that of theconventional manual operated flush valve.

In addition, the structural design of the solenoid operated automaticflush valve is different from that of the manual operated flush valve.In other words, when the flushing system is incorporated with thesolenoid operated automatic flush valve, the flushing system will losethe mechanical-manual operated feature. Therefore, there is noalternative to operate the flushing cycle when the solenoid operatedautomatic flush valve has failed to operate.

In order to install the solenoid operated automatic flush valve into theconventional flushing system, the mechanical-manual operating mechanismof the flush valve must be totally removed, which is a waste ofresources in order to incorporated with the solenoid operated automaticflush valve.

The configuration of the solenoid operated automatic flush valve iscomplicated, wherein once the solenoid is broken or the battery is dead,the facility should call a technician to open an outer cover anddisassemble an inner cover for the replacement of the solenoid or thebattery. Due to the complicated structure of the solenoid operatedautomatic flush valve, the solenoid operated automatic flush valverequires a skilled technician to replace the broken solenoid and/or evenreplace the battery, which may further increase the maintenance cost ofthe infrared operated automatic flush valve.

Most of the automatic flush valves cannot adjust each configurations ofthe flushing cycle to meet the specific requirements. For example,during the baseball game, the toilets in public facility in a baseballstadium need a relatively larger volume of flushing water to keep thetoilet empty and clean due to the frequently use of the toilets. Takethe restroom in the restaurant for another instance. During the non rushhours, such as in the afternoon, the restaurant may only need smalleramount of flushing water since fewer customers in this period, so as toprevent wasting flushing water.

Therefore, there exists a great need for controlling each of theflushing cycles of the automatic toilet to meet the differentrequirements and situations of using the automatic toilet.

SUMMARY OF THE PRESENT INVENTION

The invention is advantageous in that it provides an actuation controlfor the flush apparatus, which comprises a cartridge valve to beselectively actuated between an opened position and a closed positionfor completing a flushing cycle of the flush apparatus without anyrequirement of water cavity or diaphragm.

Another advantage of the invention is to provide an actuation controlfor the flush apparatus, wherein the cartridge valve is orientatedtransversely, preferably perpendicularly, to the water-in direction thatthe cartridge valve bears almost no water pressure when the cartridgevalve is moved between the opened position and the closed position.

Another advantage of the invention is to provide an actuation controlfor the flush apparatus, which generates power torque as the actuationforce to actuate the cartridge valve, such that the cartridge valve isable to control a high water pressure from the water source.

Another advantage of the invention is to provide an actuation controlfor the flush apparatus, wherein since the flush apparatus does notcontain any water cavity or diaphragm, the size of the flush apparatuscan be minimized to be installed into the flush system.

Another advantage of the invention is to provide an actuation controlfor the flush apparatus, which is capable of effectively controlling aflow volume of flush water during a flushing operation.

Another advantage of the invention is to provide an actuation controlfor the flush apparatus, which is reliable and that can be easilyinstalled and maintained.

Another advantage of the invention is to provide an actuation controlfor the flush apparatus, which is powered by an electric motor toselectively actuate the cartridge valve between the opened condition andthe closed condition.

Another advantage of the invention is to provide an actuation controlfor the flush apparatus, wherein the electric motor is used as the powergenerator to avoid water damage and to enhance performance andreliability.

Another advantage of the invention is to provide an actuation controlfor the flush apparatus, which provides an economic and efficientsolution for incorporating with the conventional flush system in asimple and economical way.

Another advantage of the invention is to provide an actuation controlfor the flush apparatus, wherein the power source is automaticallyre-charged via a charging arrangement every time during the flushingoperation of the flush apparatus.

Another object of the present invention is to provide an actuationcontrol for the flush apparatus, which does not require to alter theoriginal structural design of the flush apparatus, so as to minimize themanufacturing cost of the flush apparatus incorporating with theactuation control.

Another object of the present invention is to provide an actuationcontrol for the flush apparatus, wherein no expensive or complicatedstructure is required to employ in the present invention in order toachieve the above mentioned objects. Therefore, the present inventionsuccessfully provides an economic and efficient solution for not onlyproviding the cartridge valve to incorporate with a water-cavity-lessand diaphragm-less configuration of the flush apparatus but alsoproviding an accurate and simple flush operation via the rotatablemovement of the sealing disc.

Additional advantages and features of the invention will become apparentfrom the description which follows, and may be realized by means of theinstrumentalities and combinations particular point out in the appendedclaims.

According to the present invention, the foregoing and other objects andadvantages are attained by a diaphragm-less flush apparatus for a flushsystem, comprising a valve body and an actuation control.

The valve body has a water inlet for connecting to a water source toguide water to flow to the water inlet at a water-in direction, and awater outlet for connecting to the flush system.

The actuation control comprises a sensor for detecting a presence of auser of the flushing system, a cartridge valve, and a power generator.

The cartridge valve comprises a cartridge housing stationary supportedin the valve body at a position that a valve inlet of the cartridgehousing is located at the water inlet and the valve outlet of thecartridge housing is located at the water outlet, and a control discunit which is supported in the cartridge housing at the valve inletthereof and is orientated perpendicular to the water-in direction forbiasing against water pressure from the water source, wherein thecontrol disc unit is driven to move between a closed position to closethe valve inlet for blocking the water to pass through the valve inlet,and an opened position to open up the valve inlet for allowing the waterpassing to the water outlet through the valve outlet so as to complete aflushing cycle of the flush system.

The power generator is activated by the sensor and is operatively linkedto the cartridge valve to drive the control disc unit between the closedposition and the opened position.

In accordance with another aspect of the invention, the presentinvention comprises an actuation control for controlling volume of waterused in a flushing cycle of a flush system, comprising:

a cartridge valve being actuated between an opened position and a closedposition to compete the flushing cycle, wherein the cartridge valvecomprises a cartridge housing having a valve inlet for communicatingwith a water source and the valve outlet for guiding water to flow tothe flush system, and a control disc unit which is supported in thecartridge housing at the valve inlet thereof and is orientatedperpendicular to a water-in direction of the water for biasing againstwater pressure from the water source, wherein the cartridge valve isactuated at the closed position to close the valve inlet by the controldisc unit for blocking the water to pass through the valve inlet, and atthe opened position to open up the valve inlet for allowing the waterpassing to the valve outlet so as to complete the flushing cycle of theflush system; and

a control processor operatively linked to the cartridge valve forcontrollably adjusting a time of the flushing cycle and water volume forthe flushing cycle, wherein the control processor is activated inresponsive to a presence of a user of the flush system to actuate thecartridge valve for controllably adjusting the time of the flushingcycle by moving the cartridge valve between the closed position and theopened position.

In accordance with another aspect of the invention, the presentinvention comprises a method of controlling a flushing cycle of a flushsystem via a diaphragm-less flush apparatus which comprises a valve bodyhaving a water inlet and a water outlet, comprising the following steps.

(1) Support a cartridge housing of a cartridge valve in the valve bodyby the following steps.

(1.1) Align a valve inlet of the cartridge housing with the water inletwhich is connected to a water source.

(1.2) Align a valve outlet of the cartridge housing with the wateroutlet.

(1.3) Support a sealing disc of the cartridge valve in the cartridgehousing at the valve inlet at a position that the sealing disc isorientated perpendicular to a water-in direction of a flow of water forbiasing against water pressure from the water source.

(2) Retain the cartridge valve in a closed position that the valve inletis sealed and closed by the sealing disc.

(3) In responsive to a presence of a user, activate a power generator toactuate the cartridge valve from the closed position to an openedposition that the sealing disc is moved to open up the valve inlet.

(4) After completing the flushing cycle of the flush system,automatically activate the power generator to actuate the cartridgevalve back to the closed position from the opened position that thesealing disc is moved to seal and close the valve inlet.

Still further objects and advantages will become apparent from aconsideration of the ensuing description and drawings.

These and other objectives, features, and advantages of the presentinvention will become apparent from the following detailed description,the accompanying drawings, and the appended claims.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 is a front view of a flush apparatus for a flush system accordingto a preferred embodiment of the present invention, illustrating aclosed position of a cartridge valve.

FIG. 2 is a sectional view of a flush apparatus for a flush systemaccording to the above preferred embodiment of the present invention,illustrating a closed position of a cartridge valve.

FIG. 3 is a sectional view of the flush apparatus for the flush systemaccording to the above preferred embodiment of the present invention,illustrating an opened position of the cartridge valve.

FIG. 4 is an exploded perspective view of the cartridge valve of theflush apparatus for the flush system according to the above preferredembodiment of the present invention.

FIG. 5 is a side view of the of the flush apparatus for the flush systemaccording to the above preferred embodiment of the present invention,illustrating the cartridge valve being actuated between the closedposition and the opened position.

FIG. 6 is a sectional view of the cartridge valve of the flush apparatusfor the flush system according to the above preferred embodiment of thepresent invention.

FIG. 7 illustrates an alternative mode of the electric motor of theflush apparatus for the flush system according to the above preferredembodiment of the present invention.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENT

The following description is disclosed to enable any person skilled inthe art to make and use the present invention. Preferred embodiments areprovided in the following description only as examples and modificationswill be apparent to those skilled in the art. The general principlesdefined in the following description would be applied to otherembodiments, alternatives, modifications, equivalents, and applicationswithout departing from the spirit and scope of the present invention.

Referring FIGS. 1 to 3 of the drawings, a flush apparatus for a flushsystem according to a preferred embodiment of the present invention isillustrated, wherein the flush apparatus is a diaphragm-less flushapparatus that no diaphragm, no water gasket, or any elastic film isused in the flush apparatus to retain a predetermined water pressure. Inother words, no water will be pre-filled in the flush apparatus tocreate the water pressure therein. Therefore, no water cavity is formedin the flush apparatus of the present invention. According to thepreferred embodiment, the flush apparatus comprises a valve body 10 andan actuation control 20. It is worth mentioning that the flush systemcan be a urinal or a toilet bowl.

The valve body 10 has a water inlet 11 for connecting to a water sourceto guide water to flow to the water inlet 11 at a water-in direction,and a water outlet 12 for connecting to the flush system. Accordingly,when the water is guided to flow from the water inlet 11 to the flushsystem through the water outlet 12 to complete a flushing cycle of theflush system. The valve body 10 further has a cartridge cavity 13 formedbetween the water inlet 11 and the water outlet 12. It is worthmentioning that no water is pre-filled in the cartridge cavity 13.

The actuation control 20 comprises a sensor 30, a cartridge valve 40, apower generator 50, a control processor 60, and a power chargingarrangement 70.

The sensor 30, such as an infrared sensor, is supported by the valvebody 10 and is arranged to detect the presence of a user by means ofinfrared signal in such a manner that the sensor 30 transmits aninfrared signal for detecting the presence of the user of the flushsystem.

The cartridge valve 40 is supported in the cartridge cavity 13 of thevalve body 10 to selectively guide the water to flow from the waterinlet 11 to the water outlet 12. As shown in FIGS. 2 to 4 and 6, thecartridge valve 40 comprises a cartridge housing 41 stationary supportedin the cartridge cavity 13 of the valve body 10 and a control disc unit42 supported in the cartridge housing 41.

According to the preferred embodiment, the cartridge valve 40 isactuated between an opened position and a closed position to compete theflushing cycle. The flushing cycle refers to the cartridge valve 40being actuated from the closed position to the opened position and backto the closed position. The cartridge housing 41 has a valve inlet 411for communicating with a water source and a valve outlet 412 for guidingwater to flow to the flush system. The control disc unit 42 is supportedin the cartridge housing 41 at the valve inlet 411 thereof and isorientated transversely, preferably perpendicular, to a water-indirection of the water for resisting water pressure from the watersource. It is worth mentioning that the cartridge valve 40 bears almostno water pressure when the cartridge valve 40 is moved between theopened position and the closed position.

The cartridge valve 40 is actuated at the closed position to close thevalve inlet 411 by the control disc unit 42 for blocking the water topass through the valve inlet 411, and at the opened position to open upthe valve inlet 411 for allowing the water passing to the valve outlet412 so as to complete the flushing cycle of the flush system.

In particular, the valve inlet 411 is located at and coaxially alignedwith the water inlet 11 of the valve body 10 and the valve outlet 412 islocated at and coaxially aligned with the water outlet 12 of the valvebody 10. Therefore, when the water passes through the water inlet 11 tothe water outlet 12, the water must pass through the valve inlet 411 tothe valve outlet 412 of the cartridge housing 41.

In one embodiment, the cartridge housing 41 has a tubular surroundingwall 413 defining an open end and a closed end, wherein the valve inlet411 is formed at the open end of the surrounding wall 413 and the valveoutlet 412 is formed at the surrounding wall 413 between the open endand the closed end.

The control disc unit 42 is supported in the surrounding wall 413 of thecartridge housing 41 and is orientated transverse, preferablyperpendicular, to the water-in direction of the water flowing at thevalve inlet 411, i.e. the water-in direction at the water outlet 12, forresisting water pressure from the water source. Accordingly, the controldisc unit 42 is driven to move between the closed position, as shown inFIG. 2, to close the valve inlet 411 for blocking the water to passthrough the valve inlet 411, and the opened position, as shown in FIG.3, to open up the valve inlet 411 for allowing the water passing to thewater outlet 12 through the valve outlet 412 so as to complete theflushing cycle of the flush system.

As shown in FIGS. 2 to 4, the control disc unit 42 comprises a sealingdisc 421 rotatably coupled within the surrounding wall 413 at the openend thereof to selectively close the valve inlet 411, and a controlshaft 422 extended from the sealing disc 421 through the closed end ofthe surrounding wall 413 to operatively couple with the power generator50 so as to drive the sealing disc 421 to rotate between the closedposition and the opened position. Preferably, the sealing disc 421 ismade of ceramic or other durable material such as platinum.

The sealing disc 421 has a flat pressuring surface 4211 perpendicular tothe water-in direction at the valve inlet 411 for resisting waterpressure from the water source. For example, when the water-in directionat the valve inlet 411 refers to the water passing at the valve inlet411 at the horizontal direction, the flat pressuring surface 4211 of thesealing disc 421 is vertically supported to withstand the water pressurefrom the water source. It is worth mentioning that the water pressure iscreated from the water source but not within the valve body 10 or thecartridge valve 40.

As shown in FIG. 4, the control disc unit 42 further comprises astationary disc 410, having a plurality of valve sectors 414, sealed atthe open end of the surrounding wall 413 to define a plurality ofopening sectors 415 alternating with the valve sectors 414, such thatthe control disc unit 42 is moved at the closed position when thesealing disc 421 is rotated to close the opening sectors 415. In otherwords, the opening sectors 415 are uncovered when the control disc unit42 is moved at the opened position to allow the water entering throughthe opening sectors 415. Accordingly, the valve sectors 414 are radiallyextended from a center of the surrounding wall 413 to a peripheral edgethereof. In one embodiment, two valve sectors 414 are formed at the openend of the surrounding wall 413 and two opening sectors 415 are definedat the open end of the surrounding wall 413. Preferably, an area of eachvalve sector 414 is larger than an area of the opening sector 415.

The sealing disc 421 comprises a plurality of disc sectors 4212corresponding to the valve sectors 414, wherein the flat pressuringsurface 4211 is defined on each of the disc sectors 4211. Accordingly,when the sealing disc 421 is rotated to align the disc sectors 4211 withthe valve sectors 414 respectively, the opening sectors 415 are openedfor allowing the water to pass through, and when the sealing disc 421 isrotated to align the disc sectors 4212 with the opening sectors 415respectively, the opening sectors 415 are sealed and closed for blockingthe water to pass through. Accordingly, the area of each of the discsectors 4212 is at least the same as the area of the valve sector 414,such that the disc sector 4212 is big enough to cover and seat at theopening sector 415. As shown in FIG. 5, when the sealing disc 421 isrotated at one direction, the disc sectors 4212 are moved to align withthe valve sectors 414, such that the opening sectors 415 are opened upto allow the water to flow into the valve inlet 411 to start the flushoperation. When the sealing disc 421 is rotated at an oppositedirection, the disc sectors 4212 are moved to align with and seal at theopening sectors 415, such that the flat pressuring surfaces 4211 of thedisc sectors 4212 will block the water to flow into the valve inlet 411.It is worth mentioning that the rotational direction of the sealing disc421 is perpendicular to the water-in direction of water at the waterinlet 11.

Accordingly, the stationary disc 410 and the sealing disc 421 are madeof ceramic material, wherein the stationary disc 410 and the sealingdisc 421 are biased against each other. In other words, the innersurface of the stationary disc 410 is engaged with the outer surface,i.e. the flat pressuring surface 4211, of the sealing disc 421. It isworth mentioning that the two surfaces of the stationary disc 410 andthe sealing disc 421 are coupled with each other via a mutual attractiveforce. In addition, due to the ceramic material, the sealing disc 421 isdriven to rotate with almost frictionless to the stationary disc 410. Inorder to overcome the attractive force between the stationary disc 410and the sealing disc 421 to enhance the rotational movement of thesealing disc 421 with respect to the stationary disc 410, the sealingdisc 421 further has a plurality of indentions 4210 formed at the discsectors 4212 to minimize the contacting surface engagement between thestationary disc 410 and the sealing disc 421. Therefore, the attractiveforce is strong enough to retain the positioning relationship betweenthe sealing disc 421 and the stationary disc 410 and is weak enough toallow the sealing disc 421 to smoothly rotate with respect to thestationary disc 410.

The sealing disc 421 further comprises a plurality of disc arms 4213extended from the disc sectors 4212 respectively with the surroundingwall 413 and a plurality of disc openings 4214 formed between two of thedisc arms 4213. When the sealing disc 421 is rotated at one direction toalign the disc sectors 4212 align with the valve sectors 414, at leastone of the disc openings 4214 is aligned with the valve outlet 412 toallow the water to flow out of the valve outlet 412. When the sealingdisc 421 is rotated at an opposite direction to align and seal the discsectors 4212 at the opening sectors 415, at least one of the disc arms4213 is aligned with and sealed at the valve outlet 412 to block thewater to flow out of the valve outlet 412. In other words, the sealingdisc 421 is rotated to seal and block the valve inlet 411 by the discsectors 4212 and to seal and block the valve outlet 412 by the disc arm4213 to ensure no water to be flow from the water inlet 11 to the wateroutlet 12.

The control shaft 422 is coaxially extended from the sealing disc 421 todrive the sealing disc 421 to rotate. In particular, the control shaft422 is operatively coupled to the power generator 50. It is worthmentioning that the control shaft 422 has a driving end 4221 extendedinto the closed end of the surrounding wall 413 to drive the sealingdisc 421 to rotate, and a driven end extended out of the closed end ofthe surrounding wall 413 to detachably couple with the power generator50. Therefore, in case of the malfunction of the cartridge valve 40, thecartridge valve 40 can be removed from the valve body 10 and a newcartridge valve 40 can be replaced to be installed into the valve body10. In particular, the sealing disc 421 has an engaging slot formed at arear side thereof to engage with the driving end of the control shaft422. Accordingly, the engaging slot is an elongated slot indented on therear side of the sealing disc 421 to engage with the driving end of thecontrol shaft 422, such that when the driven end of the control shaft422 is rotated by the power generator 50, the sealing disc 421 is drivento rotate within the surrounding wall 413.

In order to prevent the rotational movement of the stationary disc 410within the surrounding wall 413, the surrounding wall 413 further has atleast a positioning slot 4131 formed at an inner wall surface of thesurrounding wall 413. The stationary disc 410 further comprises at leasta positioning protrusion 4101 radially and outwardly protrudedtherefrom, such that when the stationary disc 410 is coaxially receivedin the surrounding wall 413, the positioning protrusion 4101 is receivedat the positioning slot 4131 to prevent the stationary disc 410 frombeing rotated within the surrounding wall 413.

As shown in FIG. 4, the control disc unit 42 further comprises a sealingunit 423. The sealing unit 423 comprises a sealing gasket 4231 having aring shape sealed at the open end of the surrounding wall 413 to preventthe stationary disc 410 from being slid out of the surrounding wall 413through the open end thereof. The sealing unit 423 further comprises aretention ring 4232 coaxially coupled at the sealing gasket 4231 toretain the shape of the sealing gasket 4231. It is worth mentioning thatthe sealing gasket 4231 is made of sealing material such as rubber, andthe retention ring 4232 is made of metal. When the water flows into theopen end of the surrounding wall 413, the water pressure will biasagainst the stationary disc 410 and the sealing disc 421, such that oncethe cartridge valve 40 is installed, the stationary disc 410 and thesealing disc 421 cannot be accidentally detached from the surroundingwall 413. Preferably, the control disc unit 42 further comprises asealing ring 420 coaxially coupled at an outer circumferential surfaceof the surrounding wall 413 to seal with the inner wall of the waterinlet 11.

The power source 50, which is a non-solenoid unit, comprises an electricmotor 51 for generating a rotational power and an output shaft 52operatively extended from the electric motor 51 to couple with thecontrol shaft 422 of the cartridge valve 40 so as to rotatably drive thecontrol disc unit 42 between the closed position and the openedposition. It is worth to mention that the electric motor 51 is preferredand is more reliable than the solenoid because the electric motor 51provides simple mechanical work rather than using the magnetic force, soas to minimize the failure operation of the electric motor 51 and toreduce the maintenance cost of the present invention. In addition, thesize of the electric motor 51 is so small in comparison with thesolenoid so as to reduce the overall size of the electric motor 51.Therefore, the electric motor 51 is preferred to be used to not onlyensure the reliable of the electric motor 51 but also enhance the smoothoperation thereof. It is worth mentioning that the output shaft 52 isdetachably coupled at the driven end of the control shaft 422 todirectly transmit the rotational power from the electric motor 51 to thecontrol shaft 422 through the output shaft 52.

As shown in FIGS. 2 to 4, the electric motor 51 is located at a side ofthe cartridge valve 40, wherein the output shaft 52 is aligned with andcoupled at the control shaft 422 end-to-end. Preferably, the controlshaft 422 has a coupling slot 4220 formed at the driven end thereof,wherein the output shaft 52 is extended to engage with the coupling slotof the control shaft 422 so as to couple the output shaft 52 with thecontrol shaft 422 end-to-end. It is appreciated that the electric motor51 is located above the cartridge valve 40, as shown in FIG. 7, whereinthe output shaft 52 is coupled at the control shaft 422 via a gearmechanism 501, such that the rotational power from the output shaft 52can be transmitted to the control shaft 422 via the gear mechanism.

The control processor 60 is operatively linked to the power generator 50for controllably adjusting a time of the flushing cycle and water volumefor the flushing cycle, wherein the control processor 60 is activated inresponse to a presence of a user of the flushing system to actuate thecartridge valve 40 for controllably adjusting the time of the flushingcycle by moving the cartridge valve 40 between the opened position andthe closed position.

The control processor 60 comprises a processor unit 61 operativelylinked to the sensor 30 to receive the signal therefrom and operativelylinked to the electric motor 51 of the power generator 50 to activatethe electric motor 51 in response to the signal. Accordingly, when thesensor 30 detects the presence of the user of the flush system, thesensor 30 will generate a first actuation signal to the processor unit61. Once the processor unit 61 receives the first actuation signal, theprocessor unit 61 will activate the electric motor 51 to generate therotational power to drive the cartridge valve 40 from the closedposition to the opened position. Then, the processor unit 61 willre-activate the electric motor 51 to generate the rotational power todrive the cartridge valve 40 back to the closed position from the openedposition. Accordingly, the processor unit 61 will re-activate theelectric motor 51 when the sensor 30 detects the absence of the user ofthe flush system. For example, the user leaves the flush system that theuser is out of the detecting range of the sensor 30. The sensor 30 willgenerate a second actuation signal to the processor unit 61. Once theprocessor unit 61 receives the second actuation signal, the processorunit 61 will re-activate the electric motor 51 to drive the cartridgevalve 40 back to the closed position from the opened position.Alternatively, the processor unit 61 will re-activate the electric motor51 after a predetermined of time usage, such as 30 seconds. In otherwords, the electric motor 51 will be re-activated 30 seconds after theprocessor unit 61 receives the first actuation signal. It is worthmentioning that when the electric motor 51 is re-activated, therotational direction of the rotational power generated by the electricmotor 51 can be the same as the rotational direction of the rotationalpower generated by the electric motor 51 when the electric motor 51 isactivated initially. In particular, the control processor 60 willcontrol the rotational displacement of the sealing disc 421. In oneembodiment, the sealing disc 421 is driven to rotate from 0° (closedposition) to 90° (opened position) and is then to rotate from 90°(opened position) to 180° (closed position) to complete one flushingcycle. For next cycle, the sealing disc 421 is driven to rotate from180° (closed position) to 270° (opened position) and is then to rotatefrom 2700° (opened position) to 360° (closed position), i.e. back to 0°(closed position). Likewise, the control processor 60 can control therotational displacement of the sealing disc 421 by driving the sealingdisc 421 to rotate from 0° (closed position) to 180° (opened position)and is then to rotate from 180° (opened position) to 360° (closedposition) to complete one flushing cycle. It is worth mentioning thatthe rotational direction of the rotational power can be reversiblygenerated by the electric motor 51 that the electric motor 51 isgenerated the forward rotational power to drive the cartridge valve 40from the closed position to the opened position and the reversedrotational power to drive the cartridge valve 40 back to the closedposition from the opened position. For example, the sealing disc 421 isdriven to rotate from 0° (closed position) to 90° (opened position) andis then to rotate from 90° (opened position) back to 0° (closedposition) to complete one flushing cycle.

As it is mentioned above, the control processor 60 is operatively linkedto the power generator 50 for controllably adjusting the time of theflushing cycle. In particular, the processor unit 61 of the controlprocessor 60 controllably adjusts a time of the cartridge valve 40staying at the opened position, such that the control processor 60delays the time of the cartridge valve 40 staying at the opened positionfor increasing the water volume of the flushing cycle. In other words,by increasing the time of the cartridge valve 40 staying at the openedposition, the water volume for the flushing cycle will be increased.

Alternatively, the control processor 60 controls a rotational speed ofthe output shaft 52 for controllably adjusting the volume of water usedin the flushing cycle for the flush system. In particular, the controlprocessor 60 will control the rotational power of the electric motor 51.When the rotational speed of the output shaft 52 is reduced, the sealingdisc 421 will rotate slowly. In other words, the cartridge valve 40 willtake longer time to move from the closed position to opened position andback to the closed position. As a result, the water volume for theflushing cycle will be increased.

The control processor 60 further comprises a configuration settingarrangement 62 operatively linked to the processor unit 61 to configuredifferent volume settings. As shown in FIG. 1, the configuration settingarrangement 62 comprises a high volume control 621 and a low volumecontrol 622 for selectively adjusting the volume of water used in theflushing cycle for the flush system. Accordingly, the high volumecontrol 621 and the low volume control 622 are configured as two buttonsthat when the high volume control button is pressed, the processor unit61 is configured to control the flushing cycle for the flush system withrelatively high volume of water. Likewise, when the low volume controlbutton is pressed, the processor unit 61 is configured to control theflushing cycle for the flush system with relatively low volume of water.

The configuration setting arrangement 62 further comprises an overridecontrol 623 that activates the processor unit 61 to directly activatethe power generator 50. The override control 623 is configured as abutton that when the override control button is pressed, the processorunit 61 will activate the power generator 50 to move the cartridge valve40 from the closed position to the opened position. In other words, whenthe override control button is pressed, the flush operation isautomatically started to flush the flush system, such that the overridecontrol 623 serves as a manual flush button to manually flush the flushsystem, especially when the sensor 30 is disabled or malfunctioned.

The configuration setting arrangement 62 further comprises a timeinterval control 624 to self-start the flushing cycle everypredetermined time interval that is adjustably controlled in a timelymanner. The time interval control 624 comprises a time control panel toprogram a flush program of the processor unit 61. It is worth mentioningthat the actuation control of the present invention can be configured ina normal flush mode that the flush operation is started in response tothe presence of the user via the sensor 30, and in a timer flush modethat the flush operation is started in response to the time interval.Through the time control 624, the cartridge valve will be actuated forevery preset time interval. For example, the time interval can be presetto one hour, every two, four, six, twelve, or twenty four hoursrespectively via the time interval control 624 for starting the flushingcycle, in such a manner that a manager, such as a cleaner of a publiclavatory, is able to controllably select the time intervals of theflushing configuration regarding to variety circumstances, such asduring rush hours and off rush hours. In other words, during the rushhours, the time interval control 624 is configured to actuate the flushapparatus frequently, and during the off rush hours, the time intervalcontrol 624 is configured to actuate the flush apparatus seldom. It isworth mentioning that when the actuation control is set in the timerflush mode, the sensor 30 will be automatically deactivated because theflush operation will be started via the time interval but not the sensor30.

The power charging arrangement 70 comprises a power source 71electrically linked to the power generator 50, a propeller unit 72located at the water outlet 12, and an electrical generator 73operatively linked between the propeller unit 72 and the power source71, such that when the propeller unit 72 is driven to rotate in responseto a flush of the water coming out at the water outlet 12, theelectrical generator 73 is actuated to charge the power source 71.

According to the preferred embodiment, the power source 71 is arechargeable battery supported in the valve body 10. Alternatively, thepower source 71 can be a power outlet electrically linking with anexternal AC power supply or a solar energy collector for convertingsolar energy into electrical energy to supply the power to the electricmotor 51.

The propeller unit 72 comprises a propeller shaft 721 transverselyextended with respect to the water outlet 12 and a propeller blade 722coupled at a free end of the propeller shaft 721 at the water outlet 12such that the propeller blade 722 is driven to be rotated in response tothe flush of water so as to transmit a rotational power to theelectrical generator 73 through the propeller shaft 721. In other words,the propeller unit 72 translates water flush energy to the rotationaltorque directly related to the total blade area, i.e. more blades equalmore torque. Multiple propeller blades 722 contain a greater surfacearea on the propeller blades 722 allowing a small diameter propellersize to be effective.

The electrical generator 73, according to the preferred embodiment, isan alternator or a DC generator converting mechanical energy (rotationalforce) of the propeller unit 72 to the electrical energy. Accordingly, arectifier can be used to convert AC current to DC current if thealternator is used.

Preferably, the power charging arrangement 70 further comprises acharging housing 74 having a water guiding channel 741 connected to thewater outlet 12, wherein the propeller blade 722 is supported at thewater guiding channel 741. Accordingly, the power source 71 and theelectrical generator 73 are received in the charging housing 74.

The actuation control 20 further comprises a manual flush actuator 80comprises a manual switch 81 coupled at the cartridge valve 40 tomanually drive the cartridge valve 40 from the closed position to theopened position. Accordingly, the manual switch 81 is coupled at thecontrol shaft 422, such that when the manual switch 81 is manuallyactuated, such as pivotally actuated, the control shaft 422 is driven torotate to move the cartridge valve 40 from the closed position to theopened position. The manual flush actuator 80 further comprises aresilient element 82 coupled at the manual switch 81 to apply an urgingforce thereto for moving the manual switch 81 back to its originalposition after the manual actuation. Preferably, the resilient element82 can be a coil spring coaxially coupled at the control shaft 422 tobias against the manual switch 81, such that when the manual switch 81is pivotally pressed as an example, the resilient element 82 will becompressed. When the manual switch 81 is released, the resilient element82 will push the manual switch 81 back to the original position. It isappreciated that the resilient element 82 can be coaxially coupled atthe output shaft 52 of the power generator 50 because the control shaft422 is coupled to the output shaft 52 and is driven to rotate by theoutput shaft 52.

It is worth mentioning that each of the manual flush actuator 80 and theoverride control 623 can be manually actuated by the user to flush theflush system. Therefore, the user is able to clean the flush system andflush the flush system thereafter. Accordingly, the conventional flushapparatus requires a water tank to refill the water therein, such thatafter completing the flush operation, the flush system requires to acertain time to refill the water in the water tank for next flushoperation. Since the flush apparatus of the present invention directlycontrols the water via the cartridge valve 40, no water tank isrequired. Therefore, the user is able to flush the flush systemconsequently without any water refilling wait time.

The present invention further provides a method of controlling theflushing cycle of the flush system via the flush apparatus, comprisingthe following steps.

(1) Support the cartridge housing 41 of the cartridge valve 40 in thevalve body 10 by the following steps.

(1.1) Align the valve inlet 411 of the cartridge housing 41 with thewater inlet 11 which is connected to the water source. Preferably, thevalve inlet 411 is coaxially located within the water inlet 11 of thevalve body 10.

(1.2) Align the valve outlet 412 of the cartridge housing 41 with thewater outlet 12. Preferably, the valve outlet 412 is coaxially locatedwithin the water outlet 12 of the valve body 10.

(1.3) Support the sealing disc 421 of the cartridge valve 40 in thecartridge housing 41 at the valve inlet 411 at a position that thesealing disc 421 is orientated perpendicular to the water-in directionof the flow of water for biasing against water pressure from the watersource.

(2) Retain the cartridge valve 40 in the closed position that the valveinlet 411 is sealed and closed by the sealing disc 421.

(3) In response to a presence of a user, activate the power generator 50to actuate the cartridge valve 40 from the closed position to the openedposition that the sealing disc 421 is moved to open up the valve inlet411.

(4) After completing the flushing cycle of the flush system,automatically activate the power generator 50 to actuate the cartridgevalve 40 back to the closed position from the opened position that thesealing disc 421 is moved to seal and close the valve inlet 411. It isworth mentioning that the sealing disc 421 is rotatably supported in thecartridge housing 41, such that the sealing disc 421 is rotated at onedirection to open up of the valve inlet 411 and is rotated at an opposeddirection to close the valve inlet 411.

According to the preferred embodiment, during the flush operation, themethod further comprises a water volume control step and a powercharging step.

The water volume control step is a pre-step for controllably adjusting atime of the flushing cycle and water volume for the flushing cycle viathe control processor 60 which is operatively linked to the powergenerator 50. Accordingly, the control processor 60 controllably adjuststhe time of the cartridge valve 40 staying at the opened position, suchthat the control processor 60 delays the time of the cartridge valve 40staying at the opened position for increasing the water volume of theflushing cycle. Likewise, the control processor 60 controllably adjuststhe rotational speed of the sealing disc 421 between the opened positionand the closed position.

The power charging step comprises the following steps.

(A) Electrically link the power source 71 to the power generator 50.

(B) Support the propeller unit 72 at the water outlet 12 for beingdriven to rotate in response to a flush of the water coming out at thewater outlet 12.

(C) Operatively link the electrical generator 73 between the propellerunit 72 and the power source 71 to convert the mechanical energy fromthe propeller unit into the electrical energy to be stored in the powersource 71.

The flush apparatus of the present invention is capable of incorporatingwith most conventional flushing systems to provide the sensor operationof the flushing system with or without the flush lever for starting theflushing cycle. It is worth to mention that the cartridge valve 40 canbe embodied as the valve body 10 to further reduce the overall size ofthe flush apparatus.

The installation of the flush apparatus can be simple and easy by thesteps of removing the conventional flush apparatus and attaching theflush apparatus of the present invention to the flush system. When theflush apparatus can be incorporated with the sensor type flushapparatus, the control processor 60 will be programmed to either thenormal flush mode or the timer flush mode. When the cartridge valve 40is broken or damaged, the user is able to remove the broken cartridgevalve 40 from the valve body 10 and to replace a new cartridge valve 40to the valve body 10, such that the maintenance of the flush apparatusis easy while being cost effective.

One skilled in the art will understand that the embodiment of thepresent invention as shown in the drawings and described above isexemplary only and not intended to be limiting.

It will thus be seen that the objects of the present invention have beenfully and effectively accomplished. The embodiments have been shown anddescribed for the purposes of illustrating the functional and structuralprinciples of the present invention and is subject to change withoutdeparture from such principles. Therefore, this invention includes allmodifications encompassed within the spirit and scope of the followingclaims.

What is claimed is:
 1. A flush apparatus for a flush system, comprising:a valve body having a water inlet for connecting to a water source toguide water to flow to said water inlet at a water-in direction, and awater outlet for connecting to the flush system; and an actuationcontrol, which comprises: a cartridge valve comprising a cartridgehousing stationary supported in said valve body at a position that avalve inlet of said cartridge housing is located at said water inlet andsaid valve outlet of said cartridge housing is located at said wateroutlet, and a control disc unit which is supported in said cartridgehousing at said valve inlet thereof and is orientated transversely tothe water-in direction for resisting water pressure from said watersource, wherein said control disc unit is able to be driven to movebetween a closed position to close said valve inlet for blocking thewater to pass through said valve inlet, and an opened position to openup said valve inlet for allowing the water passing to said water outletthrough said valve outlet so as to complete a flushing cycle of theflush system.
 2. The flush apparatus, as recited in claim 1, whereinsaid cartridge housing has a tubular surrounding wall defining an openend as said valve inlet and said valve outlet is formed at saidsurrounding wall of said cartridge housing to align with said wateroutlet.
 3. The flush apparatus, as recited in claim 2, wherein saidcontrol disc unit comprises a sealing disc rotatably coupled within saidsurrounding wall at said open end thereof to selectively close saidvalve inlet, and a control shaft extended from said sealing disc througha closed end of said surrounding wall to operatively couple with saidpower generator so as to drive said sealing disc to rotate between saidclosed position and said opened position.
 4. The flush apparatus, asrecited in claim 3, wherein said sealing disc has a flat pressuringsurface perpendicular to the water-in direction for biasing againstwater pressure from said water source.
 5. The flush apparatus, asrecited in claim 3, wherein said control disc unit further comprises astationary disc non-rotatably coupled at said cartridge housing, whereinsaid stationary disc comprises a plurality of valve sectors spacedlysealed at said open end of said surrounding wall and a plurality ofopening sectors alternating with said valve sectors, such that saidcontrol disc unit is moved at said closed position when said sealingdisc is rotated to close said opening sectors.
 6. The flush apparatus,as recited in claim 4, wherein said sealing disc comprises a pluralityof disc sectors corresponding to said valve sectors, such that when saidsealing disc is rotated to align said disc sectors with said valvesectors respectively, said opening sectors are opened for allowing thewater to pass through, and when said sealing disc is rotated to alignsaid disc sectors with said opening sectors respectively, said openingsectors are sealed and closed for blocking the water to pass through. 7.The flush apparatus, as recited in claim 1, further comprising a powergenerator, which is activated by said sensor, operatively linked to saidcartridge valve to drive said control disc unit between said closedposition and said opened position.
 8. The flush apparatus, as recited inclaim 7, wherein said power generator comprises an electric motor forgenerating a rotational power and an output shaft operatively extendedfrom said electric motor to couple with said cartridge valve so as torotatably drive said control disc unit between said closed position andsaid opened position.
 9. The flush apparatus, as recited in claim 7,wherein said power generator, which is a non-solenoid unit, comprises anelectric motor for generating a rotational power and an output shaftoperatively extended from said electric motor to couple with saidcontrol shaft of said cartridge valve so as to rotatably drive saidcontrol disc unit between said closed position and said opened position.10. The flush apparatus, as recited in claim 8, wherein said actuationcontrol further comprises a power charging arrangement which comprises apower source electrically linked to said power generator, a propellerunit located at said water outlet and an electrical generatoroperatively linked between said propeller unit and said power source,such that when said propeller unit is driven to rotate in response to aflush of the water coming out at said water outlet, said electricalgenerator is actuated to charge said power source.
 11. The flushapparatus, as recited in claim 9, wherein said actuation control furthercomprises a power charging arrangement which comprises a power sourceelectrically linked to said power generator, a propeller unit located atsaid water outlet and an electrical generator operatively linked betweensaid propeller unit and said power source, such that when said propellerunit is driven to rotate in response to a flush of the water coming outat said water outlet, said electrical generator is actuated to chargesaid power source.
 12. The flush apparatus, as recited in claim 7,wherein said actuation control further comprises a control processoroperatively linked to said power generator for controllably adjusting atime of said flushing cycle and water volume for said flushing cycle,wherein said control processor is activated in response to a presence ofa user of said flushing system to actuate said cartridge valve forcontrollably adjusting said time of said flushing cycle by moving saidcartridge valve between said opened position and said closed position.13. The flush apparatus, as recited in claim 5, further comprising apower generator, which is activated by said sensor, operatively linkedto said cartridge valve to drive said control disc unit between saidclosed position and said opened position.
 14. The flush apparatus, asrecited in claim 13, wherein said power generator comprises an electricmotor for generating a rotational power and an output shaft operativelyextended from said electric motor to couple with said cartridge valve soas to rotatably drive said control disc unit between said closedposition and said opened position.
 15. The flush apparatus, as recitedin claim 13, wherein said power generator, which is a non-solenoid unit,comprises an electric motor for generating a rotational power and anoutput shaft operatively extended from said electric motor to couplewith said control shaft of said cartridge valve so as to rotatably drivesaid control disc unit between said closed position and said openedposition.
 16. The flush apparatus, as recited in claim 14, wherein saidactuation control further comprises a power charging arrangement whichcomprises a power source electrically linked to said power generator, apropeller unit located at said water outlet and an electrical generatoroperatively linked between said propeller unit and said power source,such that when said propeller unit is driven to rotate in response to aflush of the water coming out at said water outlet, said electricalgenerator is actuated to charge said power source.
 17. The flushapparatus, as recited in claim 15, wherein said actuation controlfurther comprises a power charging arrangement which comprises a powersource electrically linked to said power generator, a propeller unitlocated at said water outlet and an electrical generator operativelylinked between said propeller unit and said power source, such that whensaid propeller unit is driven to rotate in response to a flush of thewater coming out at said water outlet, said electrical generator isactuated to charge said power source.
 18. The flush apparatus, asrecited in claim 13, wherein said actuation control further comprises acontrol processor operatively linked to said power generator forcontrollably adjusting a time of said flushing cycle and water volumefor said flushing cycle, wherein said control processor is activated inresponse to a presence of a user of said flushing system to actuate saidcartridge valve for controllably adjusting said time of said flushingcycle by moving said cartridge valve between said opened position andsaid closed position.
 19. The flush apparatus, as recited in claim 6,further comprising a power generator, which is activated by said sensor,operatively linked to said cartridge valve to drive said control discunit between said closed position and said opened position.
 20. Theflush apparatus, as recited in claim 19, wherein said power generatorcomprises an electric motor for generating a rotational power and anoutput shaft operatively extended from said electric motor to couplewith said cartridge valve so as to rotatably drive said control discunit between said closed position and said opened position.
 21. Theflush apparatus, as recited in claim 19, wherein said power generator,which is a non-solenoid unit, comprises an electric motor for generatinga rotational power and an output shaft operatively extended from saidelectric motor to couple with said control shaft of said cartridge valveso as to rotatably drive said control disc unit between said closedposition and said opened position.
 22. The flush apparatus, as recitedin claim 20, wherein said actuation control further comprises a powercharging arrangement which comprises a power source electrically linkedto said power generator, a propeller unit located at said water outletand an electrical generator operatively linked between said propellerunit and said power source, such that when said propeller unit is drivento rotate in response to a flush of the water coming out at said wateroutlet, said electrical generator is actuated to charge said powersource.
 23. The flush apparatus, as recited in claim 21, wherein saidactuation control further comprises a power charging arrangement whichcomprises a power source electrically linked to said power generator, apropeller unit located at said water outlet and an electrical generatoroperatively linked between said propeller unit and said power source,such that when said propeller unit is driven to rotate in response to aflush of the water coming out at said water outlet, said electricalgenerator is actuated to charge said power source.
 24. The flushapparatus, as recited in claim 19, wherein said actuation controlfurther comprises a control processor operatively linked to said powergenerator for controllably adjusting a time of said flushing cycle andwater volume for said flushing cycle, wherein said control processor isactivated in response to a presence of a user of said flushing system toactuate said cartridge valve for controllably adjusting said time ofsaid flushing cycle by moving said cartridge valve between said openedposition and said closed position.
 25. The flush apparatus, as recitedin claim 1, further comprising a sensor for detecting a presence of auser of the flush system.
 26. The flush apparatus, as recited in claim18, further comprising a sensor for detecting a presence of a user ofthe flush system.
 27. The flush apparatus, as recited in claim 24,further comprising a sensor for detecting a presence of a user of theflush system.
 28. An actuation control for controlling volume of waterused in a flushing cycle of a flush system, comprising: a cartridgevalve being actuated between an opened position and a closed position tocompete said flushing cycle, wherein said cartridge valve comprises acartridge housing having a valve inlet for communicating with a watersource and said valve outlet for guiding water to flow to the flushsystem, and a control disc unit which is supported in said cartridgehousing at said valve inlet thereof and is orientated transversely to awater-in direction of the water for resisting water pressure from saidwater source, wherein said cartridge valve is actuated at said closedposition to close said valve inlet by said control disc unit forblocking the water to pass through said valve inlet, and at said openedposition to open up said valve inlet for allowing the water passing tosaid valve outlet so as to complete said flushing cycle of the flushsystem; and a control processor operatively linked to said cartridgevalve for controllably adjusting a time of said flushing cycle and watervolume for said flushing cycle, wherein said control processor isactivated in response to a presence of a user of said flush system toactuate said cartridge valve for controllably adjusting said time ofsaid flushing cycle by moving said cartridge valve between said closedposition and said opened position.
 29. The actuation control, as recitedin claim 28, wherein said control processor controllably adjusts a timeof said cartridge valve staying at said opened position, such that saidcontrol processor delays said time of said cartridge valve staying atsaid opened position for increasing said water volume of said flushingcycle.
 30. The actuation control, as recited in claim 28, furthercomprising an electric motor for generating a rotational power and anoutput shaft operatively extended from said electric motor to actuatesaid cartridge valve between said opened position and said closedposition, wherein said control processor controllably adjusts a drivenspeed of said output shaft, that is a time said output shaft drivingsaid cartridge valve to stay in said opened position, for controllablyadjusting said volume of water used in said flushing cycle for saidflush system, such that said control processor delays said driving timeof said output shaft for increasing said water volume of said flushingcycle.
 31. The actuation control, as recited in claim 30, wherein saidcontrol processor controls a rotational speed of said output shaft forcontrollably adjusting said volume of water used in said flushing cyclefor said flush system.
 32. A method of controlling a flushing cycle of aflush system via a flush apparatus which comprises a valve body having awater inlet and a water outlet, comprising the steps of: (a) providing acartridge housing of a cartridge valve in said valve body and supportinga sealing disc of said cartridge valve in said cartridge housing at saidvalve inlet at a position that said sealing disc is orientatedtransversely to a water-in direction of a flow of water for biasingagainst water pressure from said water source; (b) retaining saidcartridge valve in a closed position that said valve inlet is sealed andclosed by a sealing disc of said cartridge valve in said cartridgehousing; (c) actuating said cartridge valve from said closed position toan opened position that said sealing disc is moved to open up said valveinlet; and (d) after completing said flushing cycle of said flushsystem, actuating said cartridge valve back to said closed position fromsaid opened position that said sealing disc is moved to seal and closesaid valve inlet.
 33. The method as recited in claim 1, wherein the step(a) further comprises the steps of: (a.1) aligning said valve inlet ofsaid cartridge housing with said water inlet which is connected to awater source; and (a.2) aligning a valve outlet of said cartridgehousing with said water outlet.
 34. The method, as recited in claim 32,wherein the step (c) further comprises a step of, in response to apresence of a user, activating a power generator to actuate saidcartridge valve from said closed position to said opened position thatsaid sealing disc is moved to open up said valve inlet.
 35. The method,as recited in claim 34, where the step (d) further comprises a step ofautomatically activating said power generator to actuate said cartridgevalve back to said closed position from said opened position that saidsealing disc is moved to seal and close said valve inlet.
 36. Themethod, as recited in claim 32 wherein, in the step (a), said sealingdisc is rotatably supported in said cartridge housing, such that saidsealing disc is rotated at one direction to open up of said valve inletand is rotated at an opposed direction to close said valve inlet. 37.The method, as recited in claim 36, wherein a rotational direction ofsaid sealing disc is perpendicular to the water-in direction of water atsaid water inlet.
 38. The method, as recited in claim 37 wherein, in thestep (a), said sealing disc is rotatably supported in said cartridgehousing, such that said sealing disc is rotated at one direction to openup of said valve inlet and is rotated at an opposed direction to closesaid valve inlet, wherein a rotational direction of said sealing disc isperpendicular to the water-in direction of water at said water inlet.39. The method as recited in claim 35 wherein, in the step (c) and thestep (d), said power generator comprises an electric motor forgenerating a rotational power to rotatably actuate said sealing discbetween said closed position and said opened position.
 40. The method asrecited in claim 38 wherein, in the step (c) and the step (d), saidpower generator comprises an electric motor for generating a rotationalpower to rotatably actuate said sealing disc between said closedposition and said opened position.
 41. The method, as recited in claim32, wherein said sealing disc has a flat pressuring surfaceperpendicular to the water-in direction of water at said water inlet forbiasing against water pressure from said water source.
 42. The method,as recited in claim 40, wherein said sealing disc has a flat pressuringsurface perpendicular to the water-in direction of water at said waterinlet for biasing against water pressure from said water source.
 43. Themethod, as recited in claim 35, further comprising a power charging stepwhich comprises the steps of: electrically linking a power source tosaid power generator; supporting a propeller unit at said water outletfor being driven to rotate in response to a flush of the water comingout at said water outlet; and operatively linking an electricalgenerator between said propeller unit and said power source to convert amechanical energy from said propeller unit into an electrical energy tobe stored in said power source.
 45. The method, as recited in claim 42,further comprising a power charging step which comprises the steps of:electrically linking a power source to said power generator; supportinga propeller unit at said water outlet for being driven to rotate inresponse to a flush of the water coming out at said water outlet; andoperatively linking an electrical generator between said propeller unitand said power source to convert a mechanical energy from said propellerunit into an electrical energy to be stored in said power source. 46.The method, as recited in claim 35, further comprising a step ofcontrollably adjusting a time of said flushing cycle and water volumefor said flushing cycle via a control processor which is operativelylinked to said power generator.
 47. The method, as recited in claim 42,further comprising a step of controllably adjusting a time of saidflushing cycle and water volume for said flushing cycle via a controlprocessor which is operatively linked to said power generator.
 48. Themethod, as recited in claim 45, further comprising a step ofcontrollably adjusting a time of said flushing cycle and water volumefor said flushing cycle via a control processor which is operativelylinked to said power generator.
 49. The method, as recited in claim 47,wherein said control processor controllably adjusts a time of saidcartridge valve staying at said opened position, such that said controlprocessor delays said time of said cartridge valve staying at saidopened position for increasing said water volume of said flushing cycle.50. The method, as recited in claim 48, wherein said control processorcontrollably adjusts a rotational speed of said sealing disc betweensaid opened position and said closed position.